/** @file can.c 
*   @brief CAN Driver Source File
*   @date 15.July.2015
*   @version 04.05.00
*
*   This file contains:
*   - API Functions
*   - Interrupt Handlers
*   .
*   which are relevant for the CAN driver.
*/

/* 
* Copyright (C) 2009-2015 Texas Instruments Incorporated - www.ti.com  
* 
* 
*  Redistribution and use in source and binary forms, with or without 
*  modification, are permitted provided that the following conditions 
*  are met:
*
*    Redistributions of source code must retain the above copyright 
*    notice, this list of conditions and the following disclaimer.
*
*    Redistributions in binary form must reproduce the above copyright
*    notice, this list of conditions and the following disclaimer in the 
*    documentation and/or other materials provided with the   
*    distribution.
*
*    Neither the name of Texas Instruments Incorporated nor the names of
*    its contributors may be used to endorse or promote products derived
*    from this software without specific prior written permission.
*
*  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 
*  "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 
*  LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
*  A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 
*  OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 
*  SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 
*  LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
*  DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
*  THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 
*  (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 
*  OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/



/* USER CODE BEGIN (0) */
/* USER CODE END */


/* Include Files */

#include "can.h"

/* USER CODE BEGIN (1) */
/* USER CODE END */


/* Global and Static Variables */

#if ((__little_endian__ == 1) || (__LITTLE_ENDIAN__ == 1))
#else
    static const uint32 s_canByteOrder[8U] = {3U, 2U, 1U, 0U, 7U, 6U, 5U, 4U};
#endif

/* USER CODE BEGIN (2) */
/* USER CODE END */


/** @fn void canInit(void)
*   @brief Initializes CAN Driver
*
*   This function initializes the CAN driver.
*
*/
/* USER CODE BEGIN (3) */
/* USER CODE END */
/* SourceId : CAN_SourceId_001 */
/* DesignId : CAN_DesignId_001 */
/* Requirements : HL_SR207 */
void canInit(void)
{
/* USER CODE BEGIN (4) */
/* USER CODE END */
    /** @b Initialize @b CAN1: */

    /** - Setup control register
    *     - Disable automatic wakeup on bus activity
    *     - Local power down mode disabled
    *     - Disable DMA request lines
    *     - Enable global Interrupt Line 0 and 1
    *     - Disable debug mode
    *     - Release from software reset
    *     - Enable/Disable parity or ECC
    *     - Enable/Disable auto bus on timer
    *     - Setup message completion before entering debug state
    *     - Setup normal operation mode
    *     - Request write access to the configuration registers
    *     - Setup automatic retransmission of messages
    *     - Disable error interrupts
    *     - Disable status interrupts
    *     - Enter initialization mode
    */
    canREG1->CTL = (uint32)0x00000000U 
                 | (uint32)0x00000000U 
                 | (uint32)((uint32)0x00000005U  << 10U)
                 | (uint32)0x00020043U;

    /** - Clear all pending error flags and reset current status */
    canREG1->ES |= 0xFFFFFFFFU;

    /** - Assign interrupt level for messages */
    canREG1->INTMUXx[0U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;

    canREG1->INTMUXx[1U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;

    /** - Setup auto bus on timer period */
    canREG1->ABOTR = (uint32)0U;

    /** - Initialize message 1 
    *     - Wait until IF1 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF1 control byte
    *     - Set IF1 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG1->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */


    canREG1->IF1MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0x000007FFU & (uint32)0x000007FFU) << (uint32)18U);
    canREG1->IF1ARB  = (uint32)0x80000000U | (uint32)0x00000000U | (uint32)0x20000000U | (uint32)((uint32)((uint32)123U & (uint32)0x000007FFU) << (uint32)18U);
    canREG1->IF1MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG1->IF1CMD  = (uint8) 0xF8U;
    canREG1->IF1NO   = 1U;

    /** - Initialize message 2 
    *     - Wait until IF2 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF2 control byte
    *     - Set IF2 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG1->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */

    canREG1->IF2MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0x000007FFU & (uint32)0x000007FFU) << (uint32)18U);
    canREG1->IF2ARB  = (uint32)0x80000000U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)((uint32)((uint32)321U & (uint32)0x000007FFU) << (uint32)18U);
    canREG1->IF2MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG1->IF2CMD  = (uint8) 0xF8U;
    canREG1->IF2NO   = 2U;

    /** - Setup IF1 for data transmission 
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG1->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG1->IF1CMD  = 0x87U;

    /** - Setup IF2 for reading data
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG1->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG1->IF2CMD = 0x17U;

    /** - Setup bit timing 
    *     - Setup baud rate prescaler extension
    *     - Setup TSeg2
    *     - Setup TSeg1
    *     - Setup sample jump width
    *     - Setup baud rate prescaler
    */
    canREG1->BTR = (uint32)((uint32)0U << 16U) |
                   (uint32)((uint32)(2U - 1U) << 12U) |
                   (uint32)((uint32)((3U + 2U) - 1U) << 8U) |
                   (uint32)((uint32)(2U - 1U) << 6U) |
                   (uint32)19U;


     /** - CAN1 Port output values */
    canREG1->TIOC =  (uint32)((uint32)1U  << 18U )
                   | (uint32)((uint32)0U  << 17U )
                   | (uint32)((uint32)0U  << 16U )                
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)1U  << 2U )    
                   | (uint32)((uint32)1U << 1U );
                   
    canREG1->RIOC =  (uint32)((uint32)1U  << 18U )    
                   | (uint32)((uint32)0U  << 17U )  
                   | (uint32)((uint32)0U  << 16U )   
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)0U  << 2U )
                   | (uint32)((uint32)0U <<1U );        

    /** - Leave configuration and initialization mode  */
    canREG1->CTL &= ~(uint32)(0x00000041U);


    /** @b Initialize @b CAN2: */

    /** - Setup control register
    *     - Disable automatic wakeup on bus activity
    *     - Local power down mode disabled
    *     - Disable DMA request lines
    *     - Enable global Interrupt Line 0 and 1
    *     - Disable debug mode
    *     - Release from software reset
    *     - Enable/Disable parity or ECC
    *     - Enable/Disable auto bus on timer
    *     - Setup message completion before entering debug state
    *     - Setup normal operation mode
    *     - Request write access to the configuration registers
    *     - Setup automatic retransmission of messages
    *     - Disable error interrupts
    *     - Disable status interrupts
    *     - Enter initialization mode
    */
    canREG2->CTL = (uint32)0x00000000U 
                 | (uint32)0x00000000U 
                 | (uint32)((uint32)0x00000005U << 10U)
                 | 0x00020043U;

    /** - Clear all pending error flags and reset current status */
    canREG2->ES |= 0xFFFFFFFFU;

    /** - Assign interrupt level for messages */
    canREG2->INTMUXx[0U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;

    canREG2->INTMUXx[1U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;


    /** - Setup auto bus on timer period */
    canREG2->ABOTR = (uint32)0U;


    /** - Initialize message 1 
    *     - Wait until IF1 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF1 control byte
    *     - Set IF1 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */


    canREG2->IF1MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0xFFFFFFFFU & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF1ARB  = (uint32)0x80000000U | (uint32)0x40000000U | (uint32)0x20000000U | (uint32)((uint32)((uint32)0x1CEC56F4U & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF1MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG2->IF1CMD  = (uint8) 0xF8U;
    canREG2->IF1NO   = 1U;

    /** - Initialize message 2 
    *     - Wait until IF2 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF2 control byte
    *     - Set IF2 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */

    canREG2->IF2MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0xFFFFFFFFU & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF2ARB  = (uint32)0x80000000U | (uint32)0x40000000U | (uint32)0x20000000U | (uint32)((uint32)((uint32)0x1CEB56F4U & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF2MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG2->IF2CMD  = (uint8) 0xF8U;
    canREG2->IF2NO   = 2U;

    /** - Initialize message 3 
    *     - Wait until IF1 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF1 control byte
    *     - Set IF1 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */

    canREG2->IF1MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0xFFFFFFFFU & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF1ARB  = (uint32)0x80000000U | (uint32)0x40000000U | (uint32)0x00000000U | (uint32)((uint32)((uint32)0x1CECF456U & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF1MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG2->IF1CMD  = (uint8) 0xF8U;
    canREG2->IF1NO   = 3U;

    /** - Initialize message 4 
    *     - Wait until IF2 is ready for use 
    *     - Set message mask
    *     - Set message control word
    *     - Set message arbitration
    *     - Set IF2 control byte
    *     - Set IF2 message number
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */

    canREG2->IF2MSK  = 0xC0000000U | (uint32)((uint32)((uint32)0xFFFFFFFFU & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF2ARB  = (uint32)0x80000000U | (uint32)0x40000000U | (uint32)0x00000000U | (uint32)((uint32)((uint32)0x456U & (uint32)0x1FFFFFFFU) << (uint32)0U);
    canREG2->IF2MCTL = 0x00001080U | (uint32)0x00000000U | (uint32)0x00000000U | (uint32)8U;
    canREG2->IF2CMD  = (uint8) 0xF8U;
    canREG2->IF2NO   = 4U;

    /** - Setup IF1 for data transmission 
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG2->IF1CMD  = 0x87U;

    /** - Setup IF2 for reading data
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG2->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG2->IF2CMD = 0x17U;

    /** - Setup bit timing 
    *     - Setup baud rate prescaler extension
    *     - Setup TSeg2
    *     - Setup TSeg1
    *     - Setup sample jump width
    *     - Setup baud rate prescaler
    */
    canREG2->BTR = (uint32)((uint32)0U << 16U) |
                   (uint32)((uint32)(2U - 1U) << 12U) |
                   (uint32)((uint32)((3U + 2U) - 1U) << 8U) |
                   (uint32)((uint32)(2U - 1U) << 6U) |
                   (uint32)19U;		


   /** - CAN2 Port output values */
    canREG2->TIOC =  (uint32)((uint32)1U  << 18U )
                   | (uint32)((uint32)0U  << 17U )
                   | (uint32)((uint32)0U  << 16U )  
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)1U  << 2U )    
                   | (uint32)((uint32)1U << 1U );
                   
    canREG2->RIOC =  (uint32)((uint32)1U  << 18U )    
                   | (uint32)((uint32)0U  << 17U )  
                   | (uint32)((uint32)0U  << 16U )   
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)0U  << 2U )
                   | (uint32)((uint32)0U <<1U );   

    /** - Leave configuration and initialization mode  */
    canREG2->CTL &= ~(uint32)(0x00000041U);

    /** @b Initialize @b CAN3: */

    /** - Setup control register
    *     - Disable automatic wakeup on bus activity
    *     - Local power down mode disabled
    *     - Disable DMA request lines
    *     - Enable global Interrupt Line 0 and 1
    *     - Disable debug mode
    *     - Release from software reset
    *     - Enable/Disable parity or ECC
    *     - Enable/Disable auto bus on timer
    *     - Setup message completion before entering debug state
    *     - Setup normal operation mode
    *     - Request write access to the configuration registers
    *     - Setup automatic retransmission of messages
    *     - Disable error interrupts
    *     - Disable status interrupts
    *     - Enter initialization mode
    */
    canREG3->CTL = (uint32)0x00000000U 
                 | (uint32)0x00000000U 
                 | (uint32)((uint32)0x00000005U << 10U)
                 | 0x00020043U;

    /** - Clear all pending error flags and reset current status */
    canREG3->ES |= 0xFFFFFFFFU;

    /** - Assign interrupt level for messages */
    canREG3->INTMUXx[0U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;
  
	canREG3->INTMUXx[1U] = (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U
                         | (uint32)0x00000000U;

    /** - Setup auto bus on timer period */
    canREG3->ABOTR = (uint32)0U;

    /** - Setup IF1 for data transmission 
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG3->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG3->IF1CMD  = 0x87U;

    /** - Setup IF2 for reading data
    *     - Wait until IF1 is ready for use 
    *     - Set IF1 control byte
    */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((canREG3->IF2STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */
    canREG3->IF2CMD = 0x17U;

    /** - Setup bit timing 
    *     - Setup baud rate prescaler extension
    *     - Setup TSeg2
    *     - Setup TSeg1
    *     - Setup sample jump width
    *     - Setup baud rate prescaler
    */
    canREG3->BTR = (uint32)((uint32)0U << 16U) |
                   (uint32)((uint32)(2U - 1U) << 12U) |
                   (uint32)((uint32)((3U + 2U) - 1U) << 8U) |
                   (uint32)((uint32)(2U - 1U) << 6U) |
                   (uint32)(uint32)19U;


    /** - CAN3 Port output values */
    canREG3->TIOC =  (uint32)((uint32)1U  << 18U )
                   | (uint32)((uint32)0U  << 17U )
                   | (uint32)((uint32)0U  << 16U )  
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)1U  << 2U )    
                   | (uint32)((uint32)1U << 1U );
                   
    canREG3->RIOC =  (uint32)((uint32)1U  << 18U )    
                   | (uint32)((uint32)0U  << 17U )  
                   | (uint32)((uint32)0U  << 16U )   
                   | (uint32)((uint32)1U  << 3U )  
                   | (uint32)((uint32)0U  << 2U )
                   | (uint32)((uint32)0U << 1U );       

    /** - Leave configuration and initialization mode  */
    canREG3->CTL &= ~(uint32)(0x00000041U);

    /**   @note This function has to be called before the driver can be used.\n
    *           This function has to be executed in privileged mode.\n
    */

/* USER CODE BEGIN (5) */
/* USER CODE END */
}

/* USER CODE BEGIN (6) */
/* USER CODE END */

/** @fn uint32 canTransmit(canBASE_t *node, uint32 messageBox, const uint8 * data)
*   @brief Transmits a CAN message
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @param[in] data Pointer to CAN TX data
*   @return The function will return:
*           - 0: When the setup of the TX message box wasn't successful   
*           - 1: When the setup of the TX message box was successful
*
*   This function writes a CAN message into a CAN message box.
*	This function is not reentrant. However, if a CAN interrupt occurs, the values of
*	the IF registers are backup up and restored at the end of the ISR, since these are a shared resource.
*
*/
/* SourceId : CAN_SourceId_002 */
/* DesignId : CAN_DesignId_002 */
/* Requirements : HL_SR208 */
uint32 canTransmit(canBASE_t *node, uint32 messageBox, const uint8 * data)
{
    uint32 i;
    uint32 success  = 0U;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

/* USER CODE BEGIN (7) */
/* USER CODE END */


    /** - Check for pending message:
    *     - pending message, return 0
    *     - no pending message, start new transmission 
    */
    if ((node->TXRQx[regIndex] & bitIndex) != 0U)
    {
        success = 0U;
    }

    else
    {
    /** - Wait until IF1 is ready for use */
    /*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
    while ((node->IF1STAT & 0x80U) ==0x80U)
    { 
    } /* Wait */

    /** - Configure IF1 for
	*     - Message direction - Write
	*     - Data Update
	*     - Start Transmission
	*/	
	node->IF1CMD = 0x87U;
	
    /** - Copy TX data into IF1 */
    for (i = 0U; i < 8U; i++)
    {
#if ((__little_endian__ == 1) || (__LITTLE_ENDIAN__ == 1))
        /*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
        node->IF1DATx[i] = *data;
        /*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
        /*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
		data++;
#else
        /*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
        node->IF1DATx[s_canByteOrder[i]] = *data;
        /*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
        /*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
		data++;
#endif
    }

    /** - Copy TX data into message box */
    /*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
    node->IF1NO = (uint8) messageBox;

    success = 1U; 
    }
    /**   @note The function canInit has to be called before this function can be used.\n
    *           The user is responsible to initialize the message box.
    */

/* USER CODE BEGIN (8) */
/* USER CODE END */

    return success;
}

/* USER CODE BEGIN (9) */
/* USER CODE END */

/** @fn uint32 canGetData(canBASE_t *node, uint32 messageBox, uint8 * const data)
*   @brief Gets received a CAN message
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @param[out] data Pointer to store CAN RX data
*   @return The function will return:
*           - 0: When RX message box hasn't received new data   
*           - 1: When RX data are stored in the data buffer   
*           - 3: When RX data are stored in the data buffer and a message was lost   
*
*   This function writes a CAN message into a CAN message box.
*
*/
/* SourceId : CAN_SourceId_003 */
/* DesignId : CAN_DesignId_003 */
/* Requirements : HL_SR209 */
uint32 canGetData(canBASE_t *node, uint32 messageBox, uint8 * const data)
{
    uint32       i;
    uint32       size;
    uint8 * pData    = data;
    uint32       success  = 0U;
    uint32       regIndex = (messageBox - 1U) >> 5U;
    uint32       bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

/* USER CODE BEGIN (10) */
/* USER CODE END */

    /** - Check if new data have been arrived:
    *     - no new data, return 0
    *     - new data, get received message 
    */
    if ((node->NWDATx[regIndex] & bitIndex) == 0U)
    {
        success = 0U;
    }

    else
    {
		/** - Wait until IF2 is ready for use */
		/*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
		while ((node->IF2STAT & 0x80U) ==0x80U)
		{ 
		} /* Wait */

		/** - Configure IF2 for
		*     - Message direction - Read
		*     - Data Read
		*     - Clears NewDat bit in the message object.
		*/	
		node->IF2CMD = 0x17U;
		
		/** - Copy data into IF2 */
		/*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
        node->IF2NO = (uint8) messageBox;

		/** - Wait until data are copied into IF2 */
		/*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
		while ((node->IF2STAT & 0x80U) ==0x80U)
		{ 
		} /* Wait */

		/** - Get number of received bytes 
		*   - Value from 0x8 to 0xF equals length 8.
		*/
		size = node->IF2MCTL & 0xFU;
		if(size > 0x8U)
		{
			size = 0x8U;
		}
		
		/** - Copy RX data into destination buffer */
		for (i = 0U; i < size; i++)
		{
#if ((__little_endian__ == 1) || (__LITTLE_ENDIAN__ == 1))
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			*pData = node->IF2DATx[i];
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */        
			/*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
			pData++;
#else
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			*pData = node->IF2DATx[s_canByteOrder[i]];
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			/*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
			pData++;
#endif
		}

		success = 1U;
	}
    /** - Check if data have been lost:
    *     - no data lost, return 1
    *     - data lost, return 3 
    */
    if ((node->IF2MCTL & 0x4000U) == 0x4000U)
    {
        success = 3U;
    }

    /**   @note The function canInit has to be called before this function can be used.\n
    *           The user is responsible to initialize the message box.
    */

/* USER CODE BEGIN (11) */
/* USER CODE END */

    return success;
}


/** @fn uint32 canGetID(canBASE_t *node, uint32 messageBox)
*   @brief Gets the Message Box's ID
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @param[out] data Pointer to store CAN RX data
*   @return The function will return the ID of the message box.
*
*   This function gets the identifier of a CAN message box.
*
*/
/* SourceId : CAN_SourceId_026 */
/* DesignId : CAN_DesignId_020 */
/* Requirements : HL_SR537 */
uint32 canGetID(canBASE_t *node, uint32 messageBox)
{
    uint32   msgBoxID  = 0U;

/* USER CODE BEGIN (10) */
/* USER CODE END */

    /** - Wait until IF2 is ready for use */
    while ((node->IF2STAT & 0x80U) ==0x80U)
    {
    } /* Wait */

	/** - Configure IF2 for
	*     - Message direction - Read
	*     - Data Read
	*     - Clears NewDat bit in the message object.
	*/
	node->IF2CMD = 0x20U;

    /** - Copy message box number into IF2 */
    /*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
    node->IF2NO = (uint8) messageBox;

    /** - Wait until data are copied into IF2 */
    while ((node->IF2STAT & 0x80U) ==0x80U)
    {
    } /* Wait */

    /* Read Message Box ID from Arbitration register. */
    msgBoxID = (node->IF2ARB & 0x1FFFFFFFU);

    return msgBoxID;

}

/** @fn uint32 canUpdateID(canBASE_t *node, uint32 messageBox, uint32 msgBoxArbitVal)
*   @brief Change CAN Message Box ID.
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*	@param[in] msgBoxArbitVal (32 bit value):
*				Bit 31 - Not used.
*				Bit 30 - 0 - The 11-bit ("standard") identifier is used for this message object.
*						 1 - The 29-bit ("extended") identifier is used for this message object.
*				Bit 29 - 0 - Direction = Receive
*						 1 - Direction = Transmit
*				Bit 28:0 - Message Identifier.
*   @return 

*
*   This function changes the Identifier and other arbitration parameters of a CAN Message Box.
*
*/
/* SourceId : CAN_SourceId_027 */
/* DesignId : CAN_DesignId_021 */
/* Requirements : HL_SR538 */
void canUpdateID(canBASE_t *node, uint32 messageBox, uint32 msgBoxArbitVal)
{

    /** - Wait until IF2 is ready for use */
    while ((node->IF2STAT & 0x80U) ==0x80U)
    {
    } /* Wait */

	/** - Configure IF2 for
	*     - Message direction - Read
	*     - Data Read
	*     - Clears NewDat bit in the message object.
	*/
	node->IF2CMD = 0xA0U;
	/* Copy passed value into the arbitration register. */
	node->IF2ARB &= 0x80000000U;
	node->IF2ARB |= (msgBoxArbitVal & 0x7FFFFFFFU);

    /** - Update message box number. */
    /*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
    node->IF2NO = (uint8) messageBox;

    /** - Wait until data are copied into IF2 */
    while ((node->IF2STAT & 0x80U) ==0x80U)
    {
    } /* Wait */

}


/* USER CODE BEGIN (12) */
/* USER CODE END */

/** @fn uint32 canSendRemoteFrame(canBASE_t *node, uint32 messageBox)
*   @brief Transmits a CAN Remote Frame.
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @param[in] data Pointer to CAN TX data
*   @return The function will return:
*           - 0: When the setup of Send Remote Frame from message box wasn't successful   
*           - 1: When the setup of Send Remote Frame from message box was successful
*
*   This function triggers Remote Frame Transmission from CAN message box.
*   Note : Enable RTR must be set in the Message x Configuration in the GUI( x: 1 - 64)    
*
*/
/* SourceId : CAN_SourceId_028 */
/* DesignId : CAN_DesignId_022 */
/* Requirements : HL_SR531 */
uint32 canSendRemoteFrame(canBASE_t *node, uint32 messageBox)
{

    uint32 success  = 0U;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

    /** - Check for pending message:
    *     - pending message, return 0
    *     - no pending message, start new transmission
    */
    if ((node->TXRQx[regIndex] & bitIndex) != 0U)
    {
        success = 0U;
    }

    else
    {
		/** - Wait until IF1 is ready for use */
		/*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
		while ((node->IF1STAT & 0x80U) ==0x80U)
		{
		} /* Wait */

		/** - Request Transmission by setting TxRqst in message box */
		node->IF1CMD  = (uint8) 0x84U;

		/** - Trigger Remote Frame Transmit from message box */
		/*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
        node->IF1NO = (uint8) messageBox;

		success = 1U;
    }
    /**   @note The function canInit has to be called before this function can be used.\n
    *           The user is responsible to initialize the message box.
    */
    return success;
}

/** @fn uint32 canFillMessageObjectData(canBASE_t *node, uint32 messageBox, const uint8 * data)
*   @brief Fills the Message Object with the data but does not initiate transmission. 
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @return The function will return:
*           - 0: When the Fill up of the TX message box wasn't successful   
*           - 1: When the Fill up of the TX message box was successful
*
*   This function fills the Message Object with the data but does not initiate transmission. 
*
*/
/* SourceId : CAN_SourceId_029 */
/* DesignId : CAN_DesignId_023 */
/* Requirements : HL_SR532 */
uint32 canFillMessageObjectData(canBASE_t *node, uint32 messageBox, const uint8 * data)
{
    uint32 i;
    uint32 success  = 0U;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);
    
    /** - Check for pending message:
    *     - pending message, return 0
    *     - no pending message, start new transmission 
    */
    if ((node->TXRQx[regIndex] & bitIndex) != 0U)
    {
        success = 0U;
    }
    else
    {
		/** - Wait until IF1 is ready for use */
		/*SAFETYMCUSW 28 D MR:NA <APPROVED> "Potentially infinite loop found - Hardware Status check for execution sequence" */
		while ((node->IF1STAT & 0x80U) ==0x80U)
		{ 
		} /* Wait */

		/** - Configure IF1 for 
		*     - Message direction - Write
		*     - Data Update
		*/	
		node->IF1CMD = 0x83U;
		
		/** - Copy TX data into IF1 */
		for (i = 0U; i < 8U; i++)
		{
#if ((__little_endian__ == 1) || (__LITTLE_ENDIAN__ == 1))
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			node->IF1DATx[i] = *data;
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			/*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
			data++;
#else
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			node->IF1DATx[s_canByteOrder[i]] = *data;
			/*SAFETYMCUSW 45 D MR:21.1 <APPROVED> "Valid non NULL input parameters are only allowed in this driver" */
			/*SAFETYMCUSW 567 S MR:17.1,17.4 <APPROVED> "Pointer increment needed" */
			data++;
#endif
		}

		/** - Copy TX data into message box */
		/*SAFETYMCUSW 93 S MR: 6.1,6.2,10.1,10.2,10.3,10.4 <APPROVED> "LDRA Tool issue" */
        node->IF1NO = (uint8) messageBox;

		success = 1U; 
    }
    
    return success;
    
}

/** @fn uint32 canIsTxMessagePending(canBASE_t *node, uint32 messageBox)
*   @brief Gets Tx message box transmission status
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @return The function will return the tx request flag
*
*   Checks to see if the Tx message box has a pending Tx request, returns
*   0 is flag not set otherwise will return the Tx request flag itself.
*/
/* SourceId : CAN_SourceId_004 */
/* DesignId : CAN_DesignId_004 */
/* Requirements : HL_SR210 */
uint32 canIsTxMessagePending(canBASE_t *node, uint32 messageBox)
{
    uint32 flag;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

/* USER CODE BEGIN (13) */
/* USER CODE END */

    /** - Read Tx request register */
    flag = node->TXRQx[regIndex] & bitIndex;

/* USER CODE BEGIN (14) */
/* USER CODE END */

    return flag;
}

/* USER CODE BEGIN (15) */
/* USER CODE END */

/** @fn uint32 canIsRxMessageArrived(canBASE_t *node, uint32 messageBox)
*   @brief Gets Rx message box reception status
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @return The function will return the new data flag
*
*   Checks to see if the Rx message box has pending Rx data, returns
*   0 is flag not set otherwise will return the Tx request flag itself.
*/
/* SourceId : CAN_SourceId_005 */
/* DesignId : CAN_DesignId_005 */
/* Requirements : HL_SR211 */
uint32 canIsRxMessageArrived(canBASE_t *node, uint32 messageBox)
{
    uint32 flag;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

/* USER CODE BEGIN (16) */
/* USER CODE END */

    /** - Read Tx request register */
    flag = node->NWDATx[regIndex] & bitIndex;

/* USER CODE BEGIN (17) */
/* USER CODE END */

    return flag;
}

/* USER CODE BEGIN (18) */
/* USER CODE END */

/** @fn uint32 canIsMessageBoxValid(canBASE_t *node, uint32 messageBox)
*   @brief Checks if message box is valid
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] messageBox Message box number of CAN node:
*              - canMESSAGE_BOX1: CAN message box 1
*              - canMESSAGE_BOXn: CAN message box n [n: 1-64]
*              - canMESSAGE_BOX64: CAN message box 64
*   @return The function will return the new data flag
*
*   Checks to see if the message box is valid for operation, returns
*   0 is flag not set otherwise will return the validation flag itself.
*/
/* SourceId : CAN_SourceId_006 */
/* DesignId : CAN_DesignId_006 */
/* Requirements : HL_SR212 */
uint32 canIsMessageBoxValid(canBASE_t *node, uint32 messageBox)
{
    uint32 flag;
    uint32 regIndex = (messageBox - 1U) >> 5U;
    uint32 bitIndex = 1U << ((messageBox - 1U) & 0x1FU);

/* USER CODE BEGIN (19) */
/* USER CODE END */

    /** - Read Tx request register */
    flag = node->MSGVALx[regIndex] & bitIndex;

/* USER CODE BEGIN (20) */
/* USER CODE END */

    return flag;
}

/* USER CODE BEGIN (21) */
/* USER CODE END */

/** @fn uint32 canGetLastError(canBASE_t *node)
*   @brief Gets last RX/TX-Error of CAN message traffic
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @return The function will return:
*           - canERROR_OK (0): When no CAN error occurred   
*           - canERROR_STUFF (1): When a stuff error occurred on RX message    
*           - canERROR_FORMAT (2): When a form/format error occurred on RX message   
*           - canERROR_ACKNOWLEDGE (3): When a TX message wasn't acknowledged  
*           - canERROR_BIT1 (4): When a TX message monitored dominant level where recessive is expected   
*           - canERROR_BIT0 (5): When a TX message monitored recessive level where dominant is expected   
*           - canERROR_CRC (6): When a RX message has wrong CRC value   
*           - canERROR_NO (7): When no error occurred since last call of this function   
*
*   This function returns the last occurred error code of an RX or TX message,
*   since the last call of this function.
*
*/
/* SourceId : CAN_SourceId_007 */
/* DesignId : CAN_DesignId_007 */
/* Requirements : HL_SR213 */
uint32 canGetLastError(canBASE_t *node)
{
    uint32 errorCode;

/* USER CODE BEGIN (22) */
/* USER CODE END */

    /** - Get last error code */
    errorCode = node->ES & 7U;

    /**   @note The function canInit has to be called before this function can be used. */

/* USER CODE BEGIN (23) */
/* USER CODE END */

    return errorCode;
}

/* USER CODE BEGIN (24) */
/* USER CODE END */

/** @fn uint32 canGetErrorLevel(canBASE_t *node)
*   @brief Gets error level of a CAN node
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @return The function will return:
*           - canLEVEL_ACTIVE (0x00): When RX- and TX error counters are below 96   
*           - canLEVEL_WARNING (0x40): When RX- or TX error counter are between 96 and 127     
*           - canLEVEL_PASSIVE (0x20): When RX- or TX error counter are between 128 and 255     
*           - canLEVEL_BUS_OFF (0x80): When RX- or TX error counter are above 255     
*
*   This function returns the current error level of a CAN node.
*
*/
/* SourceId : CAN_SourceId_008 */
/* DesignId : CAN_DesignId_008 */
/* Requirements : HL_SR214 */
uint32 canGetErrorLevel(canBASE_t *node)
{
    uint32 errorLevel;

/* USER CODE BEGIN (25) */
/* USER CODE END */

    /** - Get error level */
    errorLevel = node->ES & 0xE0U;

    /**   @note The function canInit has to be called before this function can be used. */

/* USER CODE BEGIN (26) */
/* USER CODE END */

    return errorLevel;
}

/* USER CODE BEGIN (27) */
/* USER CODE END */

/** @fn void canEnableErrorNotification(canBASE_t *node)
*   @brief Enable error notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   This function will enable the notification for the reaching the error levels warning, passive and bus off.
*/
/* SourceId : CAN_SourceId_009 */
/* DesignId : CAN_DesignId_009 */
/* Requirements : HL_SR215 */
void canEnableErrorNotification(canBASE_t *node)
{
/* USER CODE BEGIN (28) */
/* USER CODE END */

    node->CTL |= 8U;

    /**   @note The function canInit has to be called before this function can be used. */

/* USER CODE BEGIN (29) */
/* USER CODE END */
}

/* USER CODE BEGIN (30) */
/* USER CODE END */

/** @fn void canEnableStatusChangeNotification(canBASE_t *node)
*   @brief Enable Status Change notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   This function will enable the notification for the status change RxOK, TxOK, PDA, WakeupPnd Interrupt.
*/
/* SourceId : CAN_SourceId_030 */
/* DesignId : CAN_DesignId_024 */
/* Requirements : HL_SR533 */
void canEnableStatusChangeNotification(canBASE_t *node)
{

    node->CTL |= 4U;

    /**   @note The function canInit has to be called before this function can be used. */

}

/** @fn void canDisableStatusChangeNotification(canBASE_t *node)
*   @brief Disable Status Change notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   This function will disable the notification for the status change RxOK, TxOK, PDA, WakeupPnd Interrupt.
*/
/* SourceId : CAN_SourceId_031 */
/* DesignId : CAN_DesignId_025 */
/* Requirements : HL_SR534 */
void canDisableStatusChangeNotification(canBASE_t *node)
{
    node->CTL &= ~(uint32)(4U);

    /**   @note The function canInit has to be called before this function can be used. */
}

/* USER CODE BEGIN (31) */
/* USER CODE END */

/** @fn void canDisableErrorNotification(canBASE_t *node)
*   @brief Disable error notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   This function will disable the notification for the reaching the error levels warning, passive and bus off.
*/
/* SourceId : CAN_SourceId_010 */
/* DesignId : CAN_DesignId_010 */
/* Requirements : HL_SR216 */
void canDisableErrorNotification(canBASE_t *node)
{
/* USER CODE BEGIN (32) */
/* USER CODE END */

    node->CTL &= ~(uint32)(8U);

    /**   @note The function canInit has to be called before this function can be used. */

/* USER CODE BEGIN (33) */
/* USER CODE END */
}

/** @fn void canEnableloopback(canBASE_t *node, canloopBackType_t Loopbacktype)
*   @brief Disable error notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] Loopbacktype Type of Loopback:
*              - Internal_Lbk: Internal Loop Back
*              - External_Lbk: External Loop Back
*              - Internal_Silent_Lbk: Internal Loop Back with Silent mode.
*
*   This function will enable can loopback mode
*/
/* SourceId : CAN_SourceId_011 */
/* DesignId : CAN_DesignId_011 */
/* Requirements : HL_SR521 */
void canEnableloopback(canBASE_t *node, canloopBackType_t Loopbacktype)
{
    /* Enter Test Mode */
    node->CTL |= (uint32)((uint32)1U << 7U);
    
    /* Configure Loopback */
    node->TEST |= (uint32)Loopbacktype;
    
    /**   @note The function canInit has to be called before this function can be used. */
}


/** @fn void canDisableloopback(canBASE_t *node)
*   @brief Disable error notification
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   This function will disable can loopback mode
*/
/* SourceId : CAN_SourceId_012 */
/* DesignId : CAN_DesignId_012 */
/* Requirements : HL_SR522 */
void canDisableloopback(canBASE_t *node)
{

   
    node->TEST &= ~(uint32)(0x00000118U);
	
	/* Exit Test Mode */
    node->CTL &= ~(uint32)((uint32)1U << 7U);
    
    /**   @note The function canInit has to be called before this function can be used. */
}


/** @fn void canIoSetDirection(canBASE_t *node,uint32 TxDir,uint32 RxDir)
*   @brief Set Port Direction
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] TxDir - TX Pin direction
*   @param[in] RxDir - RX Pin direction
*
*   Set the direction of CAN pins at runtime when configured as IO pins.
*/
/* SourceId : CAN_SourceId_013 */
/* DesignId : CAN_DesignId_013 */
/* Requirements : HL_SR217 */
void canIoSetDirection(canBASE_t *node,uint32 TxDir,uint32 RxDir)
{
/* USER CODE BEGIN (34) */
/* USER CODE END */

    node->TIOC = ((node->TIOC & 0xFFFFFFFBU) | (TxDir << 2U));
    node->RIOC = ((node->RIOC & 0xFFFFFFFBU) | (RxDir << 2U));    

/* USER CODE BEGIN (35) */
/* USER CODE END */
}

/** @fn void canIoSetPort(canBASE_t *node, uint32 TxValue, uint32 RxValue)
*   @brief Write Port Value
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*   @param[in] TxValue - TX Pin value 0 or 1
*   @param[in] RxValue - RX Pin value 0 or 1
*
*   Writes a value to TX and RX pin of a given CAN module when configured as IO pins.
*/
/* SourceId : CAN_SourceId_014 */
/* DesignId : CAN_DesignId_014 */
/* Requirements : HL_SR218 */
void canIoSetPort(canBASE_t *node, uint32 TxValue, uint32 RxValue)
{
/* USER CODE BEGIN (36) */
/* USER CODE END */

    node->TIOC = ((node->TIOC & 0xFFFFFFFDU) | (TxValue << 1U));
    node->RIOC = ((node->RIOC & 0xFFFFFFFDU) | (RxValue << 1U));

/* USER CODE BEGIN (37) */
/* USER CODE END */
}

/** @fn uint32 canIoTxGetBit(canBASE_t *node)
*   @brief Read TX Bit
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   Reads a the current value from the TX pin of the given CAN port
*/
/* SourceId : CAN_SourceId_015 */
/* DesignId : CAN_DesignId_015 */
/* Requirements : HL_SR219 */
uint32 canIoTxGetBit(canBASE_t *node)
{
/* USER CODE BEGIN (38) */
/* USER CODE END */

    return (node->TIOC & 1U);
}

/** @fn uint32 canIoRxGetBit(canBASE_t *node)
*   @brief Read RX Bit
*   @param[in] node Pointer to CAN node:
*              - canREG1: CAN1 node pointer
*              - canREG2: CAN2 node pointer
*              - canREG3: CAN3 node pointer
*
*   Reads a the current value from the RX pin of the given CAN port
*/
/* SourceId : CAN_SourceId_016 */
/* DesignId : CAN_DesignId_016 */
/* Requirements : HL_SR220 */
uint32 canIoRxGetBit(canBASE_t *node)
{
/* USER CODE BEGIN (39) */
/* USER CODE END */

    return (node->RIOC & 1U);
}


/** @fn void can1GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
*   @brief Get the initial or current values of the CAN1 configuration registers
*
*    @param[in] *config_reg: pointer to the struct to which the initial or current 
*                           value of the configuration registers need to be stored
*    @param[in] type:     whether initial or current value of the configuration registers need to be stored
*                        - InitialValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*                        - CurrentValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*
*   This function will copy the initial or current value (depending on the parameter 'type') 
*   of the configuration registers to the struct pointed by config_reg
*
*/
/* SourceId : CAN_SourceId_017 */
/* DesignId : CAN_DesignId_017 */
/* Requirements : HL_SR224 */
void can1GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
{
    if (type == InitialValue)
    {
        config_reg->CONFIG_CTL     = CAN1_CTL_CONFIGVALUE;    
        config_reg->CONFIG_ES      = CAN1_ES_CONFIGVALUE;     
        config_reg->CONFIG_BTR     = CAN1_BTR_CONFIGVALUE;    
        config_reg->CONFIG_TEST    = CAN1_TEST_CONFIGVALUE;   
        config_reg->CONFIG_ABOTR   = CAN1_ABOTR_CONFIGVALUE;  
        config_reg->CONFIG_INTMUX0 = CAN1_INTMUX0_CONFIGVALUE;
        config_reg->CONFIG_INTMUX1 = CAN1_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX2 = CAN1_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX3 = CAN1_INTMUX3_CONFIGVALUE;
        config_reg->CONFIG_TIOC    = CAN1_TIOC_CONFIGVALUE;   
        config_reg->CONFIG_RIOC    = CAN1_RIOC_CONFIGVALUE;    
    }
    else
    {
    /*SAFETYMCUSW 134 S MR:12.2 <APPROVED> "LDRA Tool issue" */
        config_reg->CONFIG_CTL     = canREG1->CTL;   
        config_reg->CONFIG_ES      = canREG1->ES;     
        config_reg->CONFIG_BTR     = canREG1->BTR;    
        config_reg->CONFIG_TEST    = canREG1->TEST;   
        config_reg->CONFIG_ABOTR   = canREG1->ABOTR;  
        config_reg->CONFIG_INTMUX0 = canREG1->INTMUXx[0];
        config_reg->CONFIG_INTMUX1 = canREG1->INTMUXx[1];
        config_reg->CONFIG_INTMUX2 = canREG1->INTMUXx[2];
        config_reg->CONFIG_INTMUX3 = canREG1->INTMUXx[3];
        config_reg->CONFIG_TIOC    = canREG1->TIOC;
        config_reg->CONFIG_RIOC    = canREG1->RIOC;   
    }
}
/** @fn void can2GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
*   @brief Get the initial or current values of the CAN2 configuration registers
*
*    @param[in] *config_reg: pointer to the struct to which the initial or current 
*                           value of the configuration registers need to be stored
*    @param[in] type:     whether initial or current value of the configuration registers need to be stored
*                        - InitialValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*                        - CurrentValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*
*   This function will copy the initial or current value (depending on the parameter 'type') 
*   of the configuration registers to the struct pointed by config_reg
*
*/
/* SourceId : CAN_SourceId_018 */
/* DesignId : CAN_DesignId_017 */
/* Requirements : HL_SR224 */
void can2GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
{
    if (type == InitialValue)
    {
        config_reg->CONFIG_CTL     = CAN2_CTL_CONFIGVALUE;    
        config_reg->CONFIG_ES      = CAN2_ES_CONFIGVALUE;     
        config_reg->CONFIG_BTR     = CAN2_BTR_CONFIGVALUE;    
        config_reg->CONFIG_TEST    = CAN2_TEST_CONFIGVALUE;   
        config_reg->CONFIG_ABOTR   = CAN2_ABOTR_CONFIGVALUE;  
        config_reg->CONFIG_INTMUX0 = CAN2_INTMUX0_CONFIGVALUE;
        config_reg->CONFIG_INTMUX1 = CAN2_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX2 = CAN2_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX3 = CAN2_INTMUX3_CONFIGVALUE;
        config_reg->CONFIG_TIOC    = CAN2_TIOC_CONFIGVALUE;   
        config_reg->CONFIG_RIOC    = CAN2_RIOC_CONFIGVALUE;    
    }
    else
    {
    /*SAFETYMCUSW 134 S MR:12.2 <APPROVED> "LDRA Tool issue" */
        config_reg->CONFIG_CTL     = canREG2->CTL;   
        config_reg->CONFIG_ES      = canREG2->ES;     
        config_reg->CONFIG_BTR     = canREG2->BTR;    
        config_reg->CONFIG_TEST    = canREG2->TEST;   
        config_reg->CONFIG_ABOTR   = canREG2->ABOTR;  
        config_reg->CONFIG_INTMUX0 = canREG2->INTMUXx[0];
        config_reg->CONFIG_INTMUX1 = canREG2->INTMUXx[1];
        config_reg->CONFIG_INTMUX2 = canREG2->INTMUXx[2];
        config_reg->CONFIG_INTMUX3 = canREG2->INTMUXx[3];
        config_reg->CONFIG_TIOC    = canREG2->TIOC;
        config_reg->CONFIG_RIOC    = canREG2->RIOC;   
    }
}
/** @fn void can3GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
*   @brief Get the initial or current values of the CAN3 configuration registers
*
*    @param[in] *config_reg: pointer to the struct to which the initial or current 
*                           value of the configuration registers need to be stored
*    @param[in] type:     whether initial or current value of the configuration registers need to be stored
*                        - InitialValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*                        - CurrentValue: initial value of the configuration registers will be stored 
*                                       in the struct pointed by config_reg
*
*   This function will copy the initial or current value (depending on the parameter 'type') 
*   of the configuration registers to the struct pointed by config_reg
*
*/
/* SourceId : CAN_SourceId_019 */
/* DesignId : CAN_DesignId_017 */
/* Requirements : HL_SR224 */
void can3GetConfigValue(can_config_reg_t *config_reg, config_value_type_t type)
{
    if (type == InitialValue)
    {
        config_reg->CONFIG_CTL     = CAN3_CTL_CONFIGVALUE;    
        config_reg->CONFIG_ES      = CAN3_ES_CONFIGVALUE;     
        config_reg->CONFIG_BTR     = CAN3_BTR_CONFIGVALUE;    
        config_reg->CONFIG_TEST    = CAN3_TEST_CONFIGVALUE;   
        config_reg->CONFIG_ABOTR   = CAN3_ABOTR_CONFIGVALUE;  
        config_reg->CONFIG_INTMUX0 = CAN3_INTMUX0_CONFIGVALUE;
        config_reg->CONFIG_INTMUX1 = CAN3_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX2 = CAN3_INTMUX2_CONFIGVALUE;
        config_reg->CONFIG_INTMUX3 = CAN3_INTMUX3_CONFIGVALUE;
        config_reg->CONFIG_TIOC    = CAN3_TIOC_CONFIGVALUE;   
        config_reg->CONFIG_RIOC    = CAN3_RIOC_CONFIGVALUE;    
    }
    else
    {
    /*SAFETYMCUSW 134 S MR:12.2 <APPROVED> "LDRA Tool issue" */
        config_reg->CONFIG_CTL     = canREG3->CTL;   
        config_reg->CONFIG_ES      = canREG3->ES;     
        config_reg->CONFIG_BTR     = canREG3->BTR;    
        config_reg->CONFIG_TEST    = canREG3->TEST;   
        config_reg->CONFIG_ABOTR   = canREG3->ABOTR;  
        config_reg->CONFIG_INTMUX0 = canREG3->INTMUXx[0];
        config_reg->CONFIG_INTMUX1 = canREG3->INTMUXx[1];
        config_reg->CONFIG_INTMUX2 = canREG3->INTMUXx[2];
        config_reg->CONFIG_INTMUX3 = canREG3->INTMUXx[3];
        config_reg->CONFIG_TIOC    = canREG3->TIOC;
        config_reg->CONFIG_RIOC    = canREG3->RIOC;   
    }
}







